on the formal separation between lexical and phonological...
TRANSCRIPT
On the formal separation between lexical and phonological development: Converging evidence from perception and corpus studies
Yvan Rose Department of Linguistics Memorial University of Newfoundland
Sarah BlackmoreDepartment of Communication Sciences and DisordersUniversity of Alberta
Abstract
In this paper, we address relations between lexical and phonological development. We begin with an overview of the literature on infant speech perception relevant to this topic. We then engage in a systematic comparison between the lexical development of two child learners of English and their acquisition of consonants in syllable onsets. After we establish a developmental timeline for each child's onset consonant system, we consider the structure and content of their expressive vocabularies at each relevant phonological milestone. Our study fails to return tangible parallels between the two areas of development. The data instead suggest that patterns of phonological development are best described in terms of the segmental categories they involve, independent of the learners' lexicons.
Acknowledgements
We would like to thank Dr. Barbara Davis, from the University of Texas, Austin, both for her contribution of the corpus data we used in our analyses, which she shared through the PhonBank database and for her sharing of related CDI data. Without Barbara's generosity, it would have been extremely difficult to obtain access the data source required to engage with this research. We are indebted to Tania Zamuner for her tremendous feedback on a previous version of this work. We would also like to thank Dr. Sophie Kern, Director of the Laboratoire Dynamique du Langage in Lyon, who inspired some of this work in the context of the PREMS research project. Finally, we are grateful to Gregory Hedlund, the programmer of Phon, for his help with many of the technicalities related to the data mining of our corpus.
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Contents
1. Introduction...................................................................................................................................12. Background: lexicon-based approaches to phonological development........................................4
2.1 Supporting evidence..........................................................................................................62.2 Contradicting evidence......................................................................................................7
2.3 The questionable relevance of minimal pairs..................................................................102.4 Falsifiability.....................................................................................................................11
3. Current study.............................................................................................................................. 123.1 Methodology................................................................................................................... 13
3.1.1 Data collection and transcription........................................................................ 133.1.2 Corpus preparation and data mining...................................................................14
3.2 Results............................................................................................................................. 163.2.1 General measures................................................................................................16
3.2.2 Phonological development vs. lexical development...........................................183.2.3 Phonological development vs. usage frequency................................................. 22
3.3 Interim summary............................................................................................................. 233.4 The emergence of phonology as an independent system................................................ 24
4. Discussion...................................................................................................................................26
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On the formal separation between lexical and phonological development: Converging evidence from perception and corpus studies
1. Introduction
Since at least the 1970s, scholars in the area of child language phonology have reported
intriguing parallels between lexical and phonological development. One example of this comes
from patterns of lexical selection and avoidance, whereby children limit their attempts at
producing words to a subset of phonologically-identifiable word shapes, while they appear to
explicitly avoid other word shapes, whether they display particular types of syllables, sounds, or
sound combinations (Ferguson & Farwell 1975; Leonard et al. 1981; Schwartz & Leonard 1982;
see also Stoel-Gammon & Cooper 1984; Stoel-Gammon 2011; Vihman 2014). These patterns
appear to be restricted to the earliest stages of phonological development, typically when children
have small vocabularies ranging between 50 to 100 words (Stoel-Gammon 2011). This pattern
has also been reproduced experimentally, with child learners equipped with similarly-sized
vocabularies (Leonard et al. 1981; Schwartz & Leonard 1982).
However, the evidence also suggests that lexical selection and avoidance behaviours are not
found in all language learners (e.g. Stoel-Gammon & Cooper 1984; Kehoe 2015). Mentions of
selection and avoidance strategies in studies of phonological development based on even slightly
more advanced learners are, in comparison, conspicuously missing. This situation may be a
matter of focus, as these studies typically concentrate on aspects of children's phonological
productions, as opposed to potential relations between phonology and the lexicon (Smith 1973;
Fikkert 1994; Levelt 1994; Barlow 1997; Rose 2000; Goad & Rose 2004; Santos 2007; Almeida
2011; Yamaguchi 2012). However, as Stoel-Gammon (2011) points out, the nature of the
relationship between the child's lexicon and his/her phonological system remains relatively
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obscure to this day, as are its implications for related questions, for example concerning the
nature of lexical or phonological representations within the mental lexicon, or related
implications in the general area of speech processing (see also Sosa & Stoel-Gammon 2012; Ota
& Green 2013; Kehoe 2015).
Two main approaches can be identified within the literature to account for relations
between lexical and phonological development (see also Saffran & Graf Estes 2006; Curtin &
Zamuner 2014 for related discussions). The first focuses primarily on the lexicon as the driver of
phonological development draw direct relationships between the content and structure of the
child's lexicon and the level of granularity of the phonological representations of the words that
make up this lexicon: as more contrasts need to be functionally represented in the lexicon, more
detail emerges within phonological representation. This hypothesis is most explicit within the
Lexical Restructuring Model (henceforth, LRM), a hypothesis that has been widely applied to
first and second language development as well as in the area of phonological awareness and its
relationship to literacy development (Charles-Luce & Luce 1990; Walley 1993; Metsala &
Walley 1998; Luce & Pisoni 1998; Storkel 2002; Walley, Metsala & Garlock 2003; Storkel 2004;
Ballem & Plunkett 2005; Stoel-Gammon 2011; Ainsworth, Welbourne & Hesketh 2015).
Competing approaches offer more phonology-centric explanations to behaviours observed in
phonological development, in particular from the perspective of production data. These
approaches generally acknowledge long-term memory as it applies in the areas of speech
perception and lexical development as the primary source of evidence from which the
child/learner with develop phonological knowledge (Pierrehumbert 2003; Werker & Curtin 2005;
Curtin, Byers-Heinlein & Werker 2011; Munson, Edwards & Beckman 2011). However, they do
not necessarily tie the structure of the lexicon with acquisition. Phonological contrastiveness does
not act as a necessary trigger of phonological development; only the identification of categories
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and their distributions by the learner is necessary to trigger development (e.g. Goad & Rose 2004;
Lin & Mielke 2008; McAllister Byun 2009; Menn, Schmidt & Nicholas 2009; McAllister Byun,
Inkelas & Rose in press).
These approaches also highlight commonly-observed properties of children's early word
productions, which tend to display restricted inventories of sounds as well as limitations in sound
combinations. These limitations in production must also be explained in light of a growing body
of evidence suggesting that early word representations, even at a time when children do not have
many contrasts encoded in their lexicons, incorporate a high level of perceptual detail, similar to
what is behaviourally observable in adults (e.g. Swingley & Aslin 2002; Coady & Aslin 2003;
Swingley 2003; Swingley & Aslin 2007; White & Morgan 2008; Yoshida et al. 2009).
From a methodological standpoint, while cross-sectional studies comparing levels of lexical
and phonological development across young learners tend to highlight the general parallel that
exists between lexical and phonological development (without, however, demonstrating a causal
relation between the two), to our knowledge, relations between lexical and phonological
development in individual learners have never been tracked longitudinally. The current study
offers a step in this direction, in an attempt to uncover whether patterns of lexical development
may in fact offer grounds to predict patterns of phonological development, following the general
logic of the LRM.
We first provide additional background concerning this model, which we discuss in light of
the relevant literature on the development of speech perception and production abilities. After a
brief discussion of methodological and related falsifiability issues, we introduce two longitudinal
case studies of the development of North American English by child learners. We summarize
each of their patterns of consonantal productions in syllable onsets. We then compare these
patterns in light of both the phonological properties of children's expressive vocabularies and
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usage frequency in their attempted productions. As we will see, the evidence from both the
children's expressive vocabularies and usage (in production) fails to provide a reliable basis for
predicting patterns of phonological development. In contrast to this, many regularities within
each child's phonological system point to phonologically-defined classes of phones. We conclude
that models of phonological development which embrace phonetic categories (perceptual and
articulatory) at their core are better equipped to account for patterns of phonological development
than approaches based on properties of the child's lexicon.
2. Background: lexicon-based approaches to phonological development
Studies of phonological development focusing on the shape of the children’s lexicons have their
roots in the works by Leopold (1947), Menn (1971) and Waterson (1971), which emphasize the
word as a central conditioning domain for phonological behaviours. The word as a unit of
analysis is also fundamental to Ferguson & Farwell’s (1975) influential study of child phonology.
The intuitions behind these works were later adopted within 'templatic' or 'whole-word'
approaches to phonology and phonological development (see Vihman & Croft 2007; Vihman
2014 for a summary of this literature). These approaches focus primarily on word forms produced
by young children with typically very small vocabularies, highlighting similarities between these
forms, however with limited regard for the extent and composition of the children’s lexicons.
This latter topic is better explored in research on how the child's developing lexicon might
influence psycholinguistic behaviours, for example in the areas of word recognition and
phonological awareness. Charles-Luce & Luce (1990) describe phonological lexicons in terms of
similarity, whereby words that share phonological characteristics (e.g. bit, pit, kit, sit, …) cluster
together within phonological 'neighbourhoods' (here, the '-it' neighbourhood). Charles-Luce &
Luce observe that early lexicons generally contain fewer phonological neighbourhoods than the
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lexicons of adult speakers of the same language, and many of these neighbourhoods can be
defined as sparse, as they are often populated by only a single or very few word forms. Charles-
Luce & Luce argue that this correlates with low level of representational detail in emerging
vocabularies, as only broad distinctions suffice to mark functional distinctions between the words
contained within these small-size lexicons. Under this view, lexical development acts as a trigger
to phonological development: as children expand their vocabularies, the words stored within their
lexicons acquire additional phonological detail, the level of which is governed by the functional
requirement to maintain phonological distinctiveness.
Building on a similar line of inquiry, but with a focus on the development of phonological
awareness and related alphabetical knowledge in older learners, Metsala (1997) and Metsala &
Walley (1998) encapsulated this general hypothesis within the Lexical Restructuring Model: "the
representations supporting spoken word recognition become increasingly segmental with spoken
vocabulary growth, and this change make possible explicit access to phonemic units" (Metsala &
Walley 1998:89).
The LRM offers a simple and plausible explanation from various theoretical perspectives,
be they rooted in functionalism or more formal models which embrace the concept of functional
contrast. The idea that children's early word forms lack in representational detail is indeed
virtually consensual among models of phonological development in production. However, as we
discuss below, direct evidence in support of this conceptually simple interpretation of the facts
has proven rather elusive, and studies in infant speech perception pose a significant challenge to
any such simplification. We review the relevant literature in the next sections.
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2.1 Supporting evidence
Central to the LRM is the claim that "young children recognize words in a more holistic manner
than do older children and adults" (Metsala & Walley 1998:100). As mentioned above, measures
of child and adult vocabularies, which show that child lexicons typically lack in neighbourhood
diversity and density, are compatible with this claim.
Evidence from studies of children's developing lexicons has also been brought in support
for the LRM. Early lexicons tend to have few neighbourhoods, which also come from frequently-
occurring words in the ambient language (Storkel 2003; Stokes 2010). These studies show that
words from dense neighbourhoods are typically acquired earlier than words from sparser
neighbourhoods (Storkel 2001; Hollich, Jusczyk & Luce 2002). These observations are
compatible with the view that high-density neighbourhoods yield increases in representational
detail within the learner's lexicon, thereby facilitating the development of frequent phones and
phone combinations. Stoel-Gammon (2011) suggests that this may be what underlies selection
and avoidance behaviours, as the child may be more inclined to avoid words which are not
represented with sufficient phonological detail.
Concerning phonological production, we can also find support for basic relationships
between phonological neighbourhood and articulatory abilities. For example, Sosa & Stoel-
Gammon (2012) show that words forming dense phonological neighbourhoods tend to be
produced by children with lower variability, in comparison to words forming sparser
phonological neighbourhoods, while word production accuracy is dependent on age of
acquisition. As we discuss below, however, the link between neighbourhood density and
variability in word production appears to hold at a certain level of granularity only; as Ota &
Green (2013) show, the segmental make-up of the words acquired by children also affects
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production accuracy in ways that transcend information about the lexicon, a topic we take up
again in section 4, in light of our analysis presented in section 3.
Finally, back in the early 1990s, the central tenets of the LRM were compatible with then-
current observations suggesting that children often fail to detect mispronunciations in early word
forms (Ferguson & Farwell 1975; Benedict 1979; Menyuk & Menn 1986; Walley 1993; Hallé &
Boysson-Bardies 1994; Hallé & Boysson-Bardies 1996). For example, Hallé & Boysson-Bardies
(1996) suggested that toddlers fail to distinguish between familiar words and modified versions
of these words, even when the modifications occur in prominent, word-initial consonants (e.g.
gâteau [ɡato] presented as *[kato]). They concluded that initial representations in children's
lexicons “have a rather global format” (Hallé & Boysson-Bardies 1996:477). However, this
conclusion has not stood the test of time, as we discuss in the next section.
2.2 Contradicting evidence
Coady & Aslin (2003) compared the productive lexicons of two learners of English against
properties of child-directed speech and adult lexical data. They showed, in line with Storkel
(2001) and Hollich, Jusczyk & Luce (2002), that neighbourhood density effects relate primarily
to the set of (frequent) words that children tend to acquire early. These frequent words also tend
to incorporate the language's most frequent sounds and sound combinations. In English, this
tendency is compounded by the fact that early-acquired words are also typically short and devoid
of phonologically complex structures (e.g. consonant clusters). Building on these results, Coady
& Aslin (2003), following an earlier line of criticism against Charles-Luce & Luce (1990) by
Dollaghan (1994), argued that in order to distinguish between the phonologically similar words
that constitute their early lexicons, children's representations must in fact afford a sufficient level
of representational detail. Coady & Aslin (2003) also related this argument to a then-emerging
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body of experimental evidence in the literature on infant speech perception suggesting that young
children's early phonological representations are in fact rich in phonetic detail.
At the forefront of this emerging literature were the studies by Swingley & Aslin (2000)
and Swingley & Aslin (2002), who showed that 14-month-old toddlers are able to detect subtle
mispronunciations in familiar words, and that this ability does not correlate with measures of
vocabulary development. These and experimental results obtained since have led to a
reinterpretation of the earlier results reported at the end of the preceding section: "[…] more
careful measurements and more sensitive experimental paradigms reveal that very young children
do show evidence of sensitivity to segmental lexical information in referential speech perception
tasks" (Coady & Aslin 2003:443; see also Ballem & Plunkett 2005; Yoshida et al. 2009). The
current view is indeed that early lexical representations contain a high level of perceptual detail,
except for phonological contexts where distributional factors independently hinder perception
(e.g. Vihman et al. 2004; Swingley 2005; Zamuner 2006; Zamuner 2009; Fikkert, Kerkhoff &
Zamuner 2006; see also Zamuner 2011 for a recent discussion of this literature).
White & Morgan (2008) conducted a series of experiments during which 19-month-old
infants were presented with pairs of known versus unfamiliar (pictures of) objects, and
simultaneously exposed to auditory stimuli falling into one of five categories: correct
pronunciations (e.g. [ʃuː] for ‘shoe’), mispronunciations affecting a single feature (e.g. [fuː], in
which only place of articulation deviates from original ‘shoe’), two features (e.g. [vuː], with
deviant place and voicing) and three features (e.g. [ɡuː], with deviant place, continuancy and
voicing) and, finally, a completely novel, unrelated form (e.g. ‘dax’). The results show that
infants are in fact extremely sensitive to mispronunciations and, furthermore, that this sensitivity
co-varies in a linear fashion with the relative degree of phonological deviance between a familiar
word and its mispronounced variant, in ways which are qualitatively similar to adult listeners
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(e.g. Milberg, Blumstein & Dworetzky 1988; Connine et al. 1997 on gradient perceptual effects
in adults).
These results were further supported by Swingley (2009), who summarizes a sizeable body
of experiments which also found no correlations between young toddlers' vocabulary sizes and
their reaction to mispronounced words (e.g. Swingley, Pinto & Fernald 1999; Swingley & Aslin
2000; Swingley & Aslin 2002; Bailey & Plunkett 2002; Swingley 2003). These results are also in
line with word learning experiments, which reveal infants' abilities to learn similar-sounding
words at relatively young ages (e.g. Ballem & Plunkett 2005; Yoshida et al. 2009).
In a more recent paper, Ota & Green (2013) further question the relationship between
lexical neighbourhoods and the development of phonological abilities. Adopting a survival
analysis approach to phonological development, they track longitudinal data from three children
documented within the English-Providence corpus available through PhonBank, with the aim of
uncovering potential correlations between phonological productive abilities and frequency
tendencies observed within the language input received by the learner. They show that lexical
input frequency is a significant predictor of the age at which target-like productions of onset
cluster types are acquired (see also Sosa & Stoel-Gammon 2012 for a similar observation based
on cross-sectional data), however with notable variability related to the segmental make-up of
specific clusters. As Ota & Green state: "Taken together with the significant main effects of
cluster types, these findings underscore the independent role played by phonological structures in
the development of sound production" (Ota & Green 2013:561). We build on this observation
below, in order to verify whether the development of individual consonants (as opposed to
consonant clusters) may itself be influenced by lexical development. As we will see, particular
phones appear to defy predictions based on either frequency or contrastiveness. We first expand
on this latter consideration in the next section.
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2.3 The questionable relevance of minimal pairs
As many of the studies cited above demonstrate, the vocabularies of young children learning
languages like English and Dutch show surprisingly few actual minimal pairs: “these results do
not support a strong role for minimal pairs in helping to refine children’s knowledge of the words
that were tested” (Swingley 2009:265).
Taken more generally, the traditional notion of minimal pair can in fact be considered more
as an easy-to-explain instructional shortcut which is arguably more useful for the instructor
teaching phonology than for the learner developing a phonological system. A language like
English, with an isolating word structure, a relatively small consonant inventory, and a high
number of commonly-used CVC forms, naturally lends itself to a contrastiveness analysis by
minimal pairs. However, not all languages display full sets of contrastive minimal pairs, which
can be rather elusive in polysynthetic or agglutinating languages, where 'words' are often too long
to lend themselves to minimal pair analyses, unless we first break them down into individual
morphemic units which themselves may not appear in isolation within spoken forms.
Contrastiveness diagnoses via minimal pairs of words also yield rather spotty results in languages
with large phonological inventories, for example in Kinyarwanda (Kimenyi 1979) or in !Xóõ
(Bradfield 2014), both of which display extremely large inventories of consonants, among other
properties. Given this, the only reliable approach to phonological contrastiveness is one that relies
on phonological distributions, which can be defined relative to prosodic properties such as stress,
word and syllable boundaries: excluding cases of phonetic free variation, a phone is contrastive to
the extent that its occurrence is not phonologically predictable within a given environment. This
logical conclusion is also reinforced by all models of phonological learning based on phone-
and/or feature-level distributional evidence (Lin & Mielke 2008; Mielke 2008; Pierrehumbert
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2003; Munson, Edwards & Beckman 2011)1,2 as well as by experimental evidence on categorical
development in the absence of minimal pairs (e.g. Maye & Gerken 2000).
Beyond its reliance on contrastive pairs of words and/or part-words, the LRM has also been
criticized for the challenges it poses in the area of falsifiability, which we discuss next.
2.4 Falsifiability
Corpus-based assessments of phonological abilities have been made much easier in recent years,
in particular given the programs and data available through the PhonBank project
(http://childes.talkbank.org/phon). However, assessments of the composition of young children's
lexicons remain methodologically extremely difficult to this day. In a nutshell, how can one
precisely assess the level of lexical development for any individual, and especially in young
learners? In turn, given that the predictions of the LRM must rely on this type of evidence, how
can one verify the validity of these predictions?
As reported by Stokes, Kern & Santos (2011), vocabulary development has largely been
assessed from various versions and adaptations of the MacArthur-Bates Communicative
Development Inventories (henceforth CDI; Fenson et al. 1993; Fenson, Marchman & Thal 2007).
These inventories consist of periodic (typically, monthly) caregiver reports on their children's
word usage, which can be used to assess lexical and related phonological characteristics of
children’s lexicons (see also Storkel 2004; Zamuner 2009; Stokes 2010; Zamuner, Morin-Lessard
& Bouchat-Laird 2015). As CDI inventories are limited both by children's potentially low rates of
communicative behaviours and/or by non-systematic compliance to the protocol on the part of the
1 In fact, as Seidl & Cristia (2012) point out, Pierrehumbert (2003) suggests that learning models do away with minimal pairs altogether and instead concentrate on positional allophones exclusively. This view underlies the approach to data analysis we pursue below.
2 This consensus across various models departs from the tenets of 'templatic' or 'whole-word' phonology, the functioning of which remains ill-defined in all areas of phonological development 'below' the word level.
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children's caregivers, these inventories are likely to underestimate the true extent of the child's
lexicon (e.g. Paul 2007).
From a more optimistic perspective, CDI data have also been shown to be generally
representative of the most prominent phonological properties of children's lexicons (Rescorla et
al. 2005; Heilmann et al. 2005). Given the predictions of the LRM, and that of word-based
approaches to phonological development more generally, we should expect to observe at least
some degree of convergence between children's phonological development and properties of their
developing lexicons. However, as we will see next, our results instead align themselves with the
contradictory evidence summarized in section 2.2 above; they suggest that the developmental
sequence in production is governed by phonetic and phonological factors, in relative
independence of the lexical contents of the children's own vocabularies.
3. Current study
We owe the datasets we analyze below to earlier empirical studies by Dr. Barbara Davis, who
conducted parallel documentations of the vocabularies (through CDI reports) and phonological
productive abilities (through naturalistic data recordings) of typically-developing children
learning American English. We selected two of these children for analysis, Georgia and Charlotte,
based on the combined availability of both their CDI and production data over a time span during
which they acquired most segmental properties of their target language. The corpora
documenting their speech productions are publicly available through PhonBank
(http://childes.talkbank.org/phon). Original publications based on these data include Davis &
MacNeilage (1995) and Davis, MacNeilage & Matyear (2002). The CDI data were most
generously provided to us directly by Dr. Davis.
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3.1 Methodology
We first summarize the methods employed by Davis and colleagues in the collection and
transcription of these data. We then describe how we organized these corpora for the purpose of
our study.
3.1.1 Data collection and transcription
The participants were located by informal referral from the surrounding community. Normal
development, including absence of hearing disorders, was established through parental report.
The CDI data were collected according to the standard protocol for CDI studies: parents were
encouraged to record, at monthly intervals, the words they identified from their children's speech
productions, using two supporting inventory questionnaires: CDI-Words and Gestures and CDI-
Word and Sentences (Fenson et al. 1993; Fenson, Marchman & Thal 2007).
CDI data were collected on 37 reports documenting Georgia's expressive vocabulary
development between the ages of 0;8.26 and 2;11.25, which includes 13 reports based on the
Words and Gestures questionnaire, collected until the child turned 1;5, and 24 reports based on
the Words and Sentences questionnaire). The data for Charlotte consist of 32 reports collected
between the child's ages of 1;0.26 and 2;7.23, and include two reports from Words and Gestures
and 30 reports based on Words and Sentences, used from the time the child was 1;3.14). In
parallel to CDI data collection, actual speech production samples were gathered through
naturalistic recordings, collected during the period spanning the children's late (canonical)
babbling and early word production stages, until they were approximately 2;11. These recordings
took place in the children’s homes, while they were interacting with their parents or other
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individuals, also with the experimenter taking part in the interaction at times, however in ways
which remained natural and observationally as neutral as possible.
The children's babbles and actual word productions were then transcribed using a
combination of IPA characters and diacritics. These transcriptions were later converted for use
into the Phon software program (Rose et al. 2006; Rose & MacWhinney 2014), and were linked
(time-aligned) to the original audio recordings, which we used every time we deemed important
to verify aspects of the original transcriptions.
3.1.2 Corpus preparation and data mining
The CDI reports were provide to us in the form of orthographic data transcripts in Phon format.
In order to attain a maximally representative vocabulary profile of each child's lexicon, we
supplemented the CDI vocabulary data with the words we found in their speech corpora at each
relevant age, and which had not been documented within the CDI reports. As we report below in
section 3.2.1, this provided a noticeable addition to our dataset.3 Using a dictionary of
pronounced forms (in citation form) built into Phon, we then assigned IPA transcriptions to each
orthographic word represented within each dataset, which provided us with an estimate of the
phonological content of the children's vocabularies throughout the development period.4
Using algorithms built into Phon, we then labelled all the IPA transcriptions for syllable
positions and obtained one-to-one phone alignments between IPA Target (model) forms and their
corresponding IPA Actual (produced) forms, which we then verified manually for maximal
3 While this effectively broadened our empirical basis for each child, it remains unclear whether this had a significant impact on the overall shape of the children's developing lexical neighbourhoods. As this comparison transcends the goals of the current study, we leave it for further research, which we hope to perform using computer-assisted methods to become available in the foreseeable future (McAllister Byun & Rose to appear).
4 One technical limitation of this method concerns the relative lack of allophonic detail available in the IPA representations of the citation forms, which imposes a certain level of granularity on the results. This is a limitation that affects every similar study in the field. In our analyses below, we limit our focus to singleton consonants located in syllable onsets, thereby controlling for much of the allophonic variation (e.g. avoiding allophonic variation between onset and coda positions, or within complex syllable constituents).
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accuracy. We illustrate these aspects of coding in Figure 1, where we can see the screen shot of a
Phon record from Georgia's production corpus. Using these alignments, we tracked all patterns of
segmental production, substitution, deletion or epenthesis that occur in the data.
Figure 1: Sample coding within Phon: Syllabification (through colour coding) and phonealignment between target and actual forms
The resulting datasets offer detailed information about the phonological structure and content of
the children's developing lexicons as well as representations of their unfolding phonological
abilities. Finally, in order to facilitate our comparisons of these two types of longitudinal data, we
divided each dataset into one-month periods.
After we completed these preparatory steps, we analyzed the corpora in an attempt to
uncover relationships between the lexical and phonological properties of the CDI and production
data. From the CDI data we extracted general measures about lexical development and
phonological neighbourhoods. From the production data we established the developmental
sequence of consonants in syllable onsets. We compare the results of these analyses in the next
section.
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3.2 Results
We begin with an overview of the two children's general levels of lexical development and
overall linguistic productivity. We then continue with more detailed information about both the
unfolding of their phonological productive abilities and the content of their developing lexicons.
3.2.1 General measures
As we can see in the next two figures, Georgia was more precocious than Charlotte in the
development of her vocabulary. Figure 2 compares the two children based on the CDI data alone,
while Figure 3 compares them based on the combined CDI and production data. A closer look at
Figure 2 also suggest a jump in vocabulary size for Georgia between 1;09 and 1;10, which
however does not appear as salient when all the available data are considered in Figure 3.5
0;0
80;
09
0;1
00;
111;
00
1;0
11;
02
1;0
31
;04
1;0
51
;06
1;0
71
;08
1;0
91
;10
1;11
2;0
02
;01
2;0
22
;03
2;0
42
;05
2;0
62
;07
2;0
82
;09
2;1
02;
11
0
250
500
750
1000
Georgia
Charlotte
Age
# of
wor
ds
Figure 2: Vocabulary size (CDI data only)
5 Also note that the jump in vocabulary size appears to take place one month earlier in Figure 3; this however is an artifact of data sampling, as CDI reports provide a (monthly-delayed) retrospective assessments of vocabulary development, while production data are associated to the date when they were recorded.
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0;0
80;
09
0;1
00;
111;
00
1;0
11;
02
1;0
31
;04
1;0
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;06
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71
;08
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;10
1;11
2;0
02
;01
2;0
22
;03
2;0
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;05
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62
;07
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;09
2;1
02;
11
0
250
500
750
1000
1250
1500
Georgia
Charlotte
Age
# of
wor
ds
Figure 3: Vocabulary size (number of word types recorded in CDI and production data)
The faster onset and higher rate of vocabulary development displayed by Georgia is also matched
by her overall higher level of linguistic productivity, as illustrated in Figure 4 through a
comparison between the two children's mean lengths of utterance throughout the period studied.6
0;11
1;0
1
1;0
3
1;0
5
1;0
7
1;0
9
1;11
2;0
1
2;0
3
2;0
5
2;0
7
2;0
9
2;11
1.00
2.00
3.00
4.00
Georgia
Charlotte
Age
ML
U
Figure 4: Mean Length of Utterance
In spite of the quantitative differences we observe between the two children, they displayed
qualitatively similar developmental curves. As we describe next, the same generally holds true of
the development of their articulatory abilities.
6 The relative stabilization of MLU observed in both children's productions at around 30 months of age suggests development in other areas of grammatical development (e.g. MacWhinney 1978; Bowerman 1982 for earlier discussions; McAllister Byun, Inkelas & Rose in press for a recent summary).
17
3.2.2 Phonological development vs. lexical development
We begin with a summary of Georgia's and Charlotte's patterns in the development of consonants
within singleton (i.e. one-consonant) syllable onsets. While other studies focusing on
phonological neighbourhood development generally restrict themselves to particular word
shapes, for example CVC word forms (e.g. Zamuner 2009), our aim differs in that we are
interested in studying the development of phonological productive abilities in light of
neighbourhood data. For sake of feasibility, we limited our research to consonants in singleton
onsets. We opted for this syllable position based on robust cross-linguistic evidence that onsets
typically offer a privileged position for the development of phonological productive abilities, a
fact also verified independently in the case of Georgia (Day 2014). Also, while we considered
singleton onsets in all word positions (except for /t,d/ in the flapping context), mastery was first
attained in word-initial onsets for every consonant where initial vs. medial contexts could be
compared at similar ages.
In the interest of clarity, we first report these data across three general time periods: the
consonants acquired before the age of 2;0, those acquired after that age, and those which were not
yet mastered by the end of the documented period, at 2;11. As we can see in Table 1, for both
children, early-acquired consonants include all target oral and nasal stops, glides, as well as
voiceless, non-dental fricatives. On the other hand, both children show slower development for
voiced fricatives, liquids and interdentals. Finally, concerning the development of affricates,
Charlotte displays a more drawn-out developmental pattern than Georgia.
18
Early (prior to 2;00) Later (2;00 or after) Not mastered (by end ofobservation period)
Georgia [p] [b] [t] [d] [k] [ɡ][m] [n][s] [ʃ] [h] [f] [w] [j][ʧ] [ʤ]
[v] [z] [l] [ɹ]
[θ] [ð]
Charlotte [p] [b] [t] [d] [k] [ɡ][m] [n][s] [ʃ] [h] [f] [w] [j]
[v] [z] [θ][ʤ][l]
[ð] [ʧ][ɹ]
Table 1: Georgia's & Charlotte's general phonological development
Keeping these general observations in mind, we now turn to comparisons between consonantal
development in production and that of phonological neighbourhoods within each child's lexicon.
Table 2 provides Georgia's phonological neighbourhood data for all target onset consonants
at the time they were mastered or, concerning the last two consonants, at the end of the
observation period. The first five columns list (a) the relevant target consonants, followed by the
child's age when (b) these consonants are first attested in the expressive vocabulary, (c) when
they are first produced in a target-like fashion, and (d) when these consonants are mastered by the
child, with mastery determined based on a majority of target-like productions within the current
and subsequent sessions, and (e) the number of times each consonant was present in singleton
onsets within attempted forms. The remaining columns provide (f) the number of attestations of
each consonant within the child's recorded vocabulary at the age of mastery as well as (g) a
breakdown of these attestations across five general neighbourhoods, represented by A (low
vowels), E (mid front vowels), I (high front vowels), O (mid back vowels) and U (high back
vowels).
19
Target Firstattestation invocabulary
First target-likeproduction
Mastery Recordedattempts at
mastery
Attestations invocabulary at
mastery
Neighbourhoods
A E I O U
b 0;08 0;10 1;00 23 18 9 3 1 3 2ɡ 0;09 1;00 1;00 2 4 0 1 1 2 0t 0;08 1;00 1;00 2 9 3 1 2 2 1m 0;08 1;01 1;01 2 6 2 0 1 3 0k 0;08 1;02 1;02 9 13 4 1 4 3 1n 0;08 1;02 1;02 1 9 5 1 0 2 1p 0;08 1;02 1;02 2 15 3 2 7 2 1d 0;08 1;04 1;04 1 13 7 0 2 4 0w 0;08 1;05 1;05 2 13 7 3 1 2 0ʃ 0;09 1;06 1;06 1 7 0 1 1 4 1h 0;08 1;05 1;06 17 24 8 5 2 8 1j 0;08 1;05 1;07 1 4 0 1 0 2 1s 0;09 1;05 1;07 19 12 3 1 5 3 0f 0;10 1;09 1;09 8 16 5 1 7 1 2
ʤ 0;08 1;09 1;09 2 8 1 2 2 2 1ʧ 0;08 1;06 1;10 4 9 2 1 6 0 0v 1;00 1;00 2;00 25 4 2 2 0 0 0z 1;02 1;09 2;01 10 2 0 0 2 0 0l 0;08 1;07 2;03 138 26 10 7 5 2 2ɹ 0;08 1;06 2;10 609 32 11 9 5 4 3θ 0;08 1;04 N/A (39) (5) 1 0 2 2 0ð 1;01 1;07 N/A (1317) (12) 0 9 2 1 0
Table 2: Georgia's development of consonants in singleton onsets
The first general observation we can draw from this table is that the age at which phones are first
attested within the lexicon, irrespective of the neighbourhood data available, does not predict
order of acquisition. For instance, although [b] and [ɹ] are both attested early in Georgia's lexicon
(at 0;08), [b] is mastered early, at 1;00, whereas [ɹ] is not acquired until much later, at 2;10. Most
target consonants are attested relatively early within the lexicon, at which point they either show
mastery or a more drawn-out developmental pattern, which we discuss further in section 3.4
below.
Table 3 replicates the same analysis for Charlotte. Again here, and in spite of the sizeable
differences in linguistic development observed between the two children in section 3.2.1, the data
20
are no more or less suggestive of a predictive link between lexical and phonological
development.
Target Firstattestation invocabulary
First target-likeproduction
Mastery Recordedattempts at
mastery
Attestations invocabulary at
mastery
Neighbourhoods
A E I O U
b 1;01 1;01 1;01 2 1 1 0 0 0 0p 1;03 1;03 1;03 3 1 0 0 0 1 0d 1;03 1;03 1;03 3 3 3 0 0 0 0ɡ 1;03 1;03 1;03 4 1 0 0 0 1 0m 1;03 1;03 1;03 8 2 1 0 0 0 1k 1;03 1;03 1;04 8 2 1 0 1 0 0j 1;04 1;04 1;04 1 1 1 0 0 0 0n 1;01 1;05 1;05 1 2 1 0 0 1 0w 1;05 1;05 1;05 1 1 0 0 0 1 0h 1;03 1;07 1;07 6 6 2 2 0 2 0s 1;03 1;08 1;08 4 3 1 0 1 1 0ʃ 1;03 1;09 1;09 2 4 1 1 0 1 1t 1;03 1;08 1;09 11 7 1 1 1 3 1f 1;09 1;09 1;11 9 6 1 0 3 1 1z 1;07 2;03 2;05 12 2 0 0 0 1 1ʤ 1;08 1;11 2;07 43 10 1 5 0 2 2l 1;10 1;11 2;07 186 21 9 4 5 1 2θ 1;03 2;01 2;09 66 6 2 1 2 1 0v 1;09 2;02 2;09 26 4 2 2 0 0 0ð 1;07 1;08 N/A (746) (9) 0 6 2 1 0ʧ 1;09 1;09 N/A (59) (17) 3 5 7 2 0ɹ 1;08 2;06 N/A (361) (25) 7 8 4 4 2
Table 3: Charlotte's development of consonants in singleton onsets
Charlotte, in line with her lower rate of vocabulary development and mean lengths of utterance
observed throughout the observation period, also acquires each target consonant at a slower rate
than Georgia. However, as already reported in Table 1 above, aside from more noticeable
difficulties with target affricates, the unfolding of her articulatory abilities is very similar to that
of Georgia.
The data also generally fail to support the hypothesis that contrastiveness within the
developing lexicon drives phonological development. At the time of mastery, some consonants
(e.g. [b, h, l, ɹ]) are found in a large number of phonological neighbourhoods in Georgia's
21
vocabulary, while others appear in only a few neighbourhoods [ɡ, j, v, z]. The same holds true of
Charlotte's data.
3.2.3 Phonological development vs. usage frequency
As usage-based approaches to language development suggest, it is possible that the figures
reported above were skewed by frequency pressures, which could have steered developmental
patterns away from purely lexical effects (e.g. Tomasello 2003; Vihman & Croft 2007; Lieven
2010; Ambridge & Lieven 2011; Ambridge et al. 2015; Vihman 2014). However, this possibility
is also hardly supported by the numbers of attempts available in each corpus: some consonants
are acquired in spite of their being seldom recorded in attempted forms, while others show late
development in spite of relatively high numbers of occurrence within target forms. In fact, as
both Day (2014, 2015) and (Blackmore in preparation) suggest, the only prediction borne out by
these datasets is that, by the time a given consonant is mastered, this consonant was already
attested in at least some actual productions, either within babbles or actual word forms.7 While
this observation may be taken as support for McCune & Vihman's (2001) proposal that
productivity predicts development, Day (2014, 2015) shows that this relation is not entirely
straightforward: a child may very well produce a phone in babbles without being able to
reproduce a similar phone (at least as perceived by human transcribers) in actual word
productions. Productivity of a certain phone thus appears to be a condition, rather than a
guarantee, for its mastery within word productions (see also Sosa & Stoel-Gammon 2006, 2012;
Sosa 2013 and references therein for related discussion). These observations by Day and
Blackmore are in line with outcomes of other studies available in the literature, which generally
fail to support usage frequency as the driving force behind phonological development in
7 We do not report on these data here as they transcend the scope of the current analysis.
22
production, even though frequency pressures may at times yank development patterns in
particular directions (Kehoe & Lleó 2003; Demuth 2007; Edwards & Beckman 2008; Rose 2009;
Ota & Green 2013; see also Brown 1973 for an early criticism of frequency-based explanations,
and Rose & Inkelas 2011 for additional discussion). For example, back to the data reported above
in Table 2 and Table 3, we can hypothesize that the slow development of the voiced fricatives [z,
v], relative to their voiceless counterparts, is at least in part influenced by the low frequency of
these consonants in the language. These results for Georgia and Charlotte suggest a role for
practice in phonological development, a factor highlighted in many recent analyses of
phonological development (e.g. Inkelas & Rose 2007; Stoel-Gammon 2011; Vihman & Keren-
Portnoy 2011; Menn, Schmidt & Nicholas 2013; Vihman 2014; McAllister Byun, Inkelas & Rose
in press). However, the way and extent to which practice actually influences phonological
development remains to be explored in more detail, for example in terms of how it can help the
child shape stable production patterns for different perceptual categories, a point we take up again
in our general discussion below.
3.3 Interim summary
Together, the results we report above conspire against views which attribute a central role for the
lexicon and lexical neighbourhoods in children's phonological development. That is not to say
that the lexicon is not important: beyond default articulations dictated by bio-mechanical aspects
of the vocal tract (e.g. MacNeilage & Davis 1990a,b; MacNeilage & Davis 2000), the commonly-
held view that sounds must be represented within lexical forms in order to be acquired remains
central. However, trajectories of phonological development appear to transcend information
about both phonological neighbourhoods and usage frequency. As we discuss further below, these
factors might instead be reflected in processing measures of production, as opposed to
23
articulatory measures, for example in terms of reaction times across various stages of
development or concerning the emergence of phonological awareness.
3.4 The emergence of phonology as an independent system
The observations in section 3.2 more convincingly point at the relative independence of
phonology as an emergent component within the children's developing systems. Within the
literature on infant speech perception, the existence of separate domains within the child's system
has recently been formalized within the PRIMIR framework (Processing Rich Information from
Multi-dimensional Interactive Representations; Werker & Curtin 2005; Curtin, Byers-Heinlein &
Werker 2011; see also Zamuner 2009 for additional discussion). Within PRIMIR, the input signal
is processed along formally independent yet inter-related levels, called 'planes'. While the original
proposal focuses on the 'General-Perceptual', 'Word', and 'Phoneme' planes, Werker, Curtin and
colleagues suggest that the system can accommodate as many planes as needed to encode
relevant properties of the ambient language, as they are identified by the learner. Unavoidably,
this must include representations for the types of motor-acoustic pairings central to the
reproduction of perceptual phonological categories in spoken forms. This is the locus of the A-
map model (McAllister Byun, Inkelas & Rose in press), a novel proposal which supplements
PRIMIR in the area of phonological production. Building on many of the assumptions behind the
Linked-Attractor model (Menn, Schmidt & Nicholas 2009), one of the aims of the A-map is to
formally capture the development of abstract associations between the perceptual categories
identified by the child and the articulatory dimensions involved in their reproduction within
speech forms (e.g. Halle & Stevens 1959; Halle & Stevens 1962; Halle & Stevens 1979; Keyser
& Stevens 2006; Stevens & Keyser 2010).
24
Recall from Table 1 that both Georgia and Charlotte acquired all target oral and nasal stops
as well as glides relatively early, and also mastered non-dental voiceless fricatives before dental
and/or voiced ones. Recall as well that Charlotte showed difficulties mastering the production of
target [ʧ] and [ʤ]. As we shift our focus away from the lexicon and consider these data from a
phonological standpoint, it is striking that all of these observations point to natural classes effects
which are firmly established within the literature on phonological theory (Clements & Ridouane
2006; Mielke 2008; Mielke 2011; Lin & Mielke 2008). In spite of potential effects from
frequency such as those noted above concerning [z] and [v], the general developmental patterns
observed in both children's data are generally in line with expectations about consonantal
development, namely that obstruent stops, nasal, and glides be mastered early, and that fricatives,
affricates, and liquids be acquired at later stages, also including the contrast between alveolar and
dental fricatives (e.g. Smit 1993; Bernhardt & Stemberger 1998; Sosa 2013). The same logic
applies to the main patterns of substitution displayed by each child during pre-mastery stages,
listed in Table 4. As we can see from these data, most substitutions involve simple phonetic
attributes, for example with regard to obstruent voicing, liquid rhoticity and laterality, or, specific
to Charlotte, the fricative release required in the production of affricates.
25
Substitution pattern Georgia CharlotteDevoicing |v| → [f]
|z| → [s]Stopping |v| → [p/b]
|z| → [d]|θ| → [d]|ð| → [d]
De-dentalization |θ| → [f] |θ| → [s]|ð| → [d]
Gliding |l| → [w] |l| → [w]|ɹ| → [w] |ɹ| → [w]
De-affrication |ʤ| → [d]|ʧ| → [t]
Table 4: Georgia's and Charlotte's main substitution patterns prior to mastery
The categorical nature of these patterns supports a view of phonology as an independent system.
While the lexicon supplies the child with target word forms, including the sounds and sound
combinations contained within these forms, the data suggests that the articulatory mastery of
these phonological units is not crucially dependent on the structure of the child's developing
lexicon.
4. Discussion
These results in fact nicely converge with those from infant speech perception studies reported in
section 2.2, which suggest that the content of the child's lexicon cannot be taken as the main
driver of phonological productive abilities. Instead, the degree of phonetic detail memorized for
each word form, and also across different phonological positions within these words, appears to
supply the relevant information, independent of functional contrastiveness. While sparse lexicons
cannot supply the learner with all of the information relevant to building an abstract system of
contrasts, it does provide perceptual targets which children must attempt to reproduce through
their own speech-motor articulations. As McAllister Byun, Inkelas & Rose (in press) argue,
articulatory productivity depends on the stability of these sensory-motor mappings across word
26
productions, even in case these mappings are inaccurate and result in phonological substitutions.
Together, these observations also suggest that functional contrastiveness, and its relation to
phonological awareness, arguably emerge at a later stage, as the child's gradually climbs the
phonological 'ladder of abstraction' (Munson, Edwards & Beckman 2011; see also Pierrehumbert
2003).
Returning briefly to the phenomenon of selection and avoidance discussed in introduction,
the results and discussion above suggest that the child's awareness of his/her own phonological
articulatory abilities, rather than the actual content of their lexicons, might be at the source of
these behaviours (Ferguson & Farwell 1975; Menn, Schmidt & Nicholas 2009).8 A formal
separation between the lexical and phonological components of the child's developing system is
also compatible with the observation we made in introduction that children appear to stop
employing selection and avoidance strategies relatively early: as soon as they have developed
reliable sensory-motor mappings for the speech sounds present in the word forms contained in
their lexicon, they no longer need to avoid these forms in production. As the development of
these mappings does not need to rely on lexical development per se, assuming the presence of a
basic lexicon, selection and avoidance behaviours can be resolved relatively early.
Importantly, however, our argument is not to dismiss the theoretical or practical relevance
of the lexicon and phonological neighbourhoods in other areas of phonological representation and
processing. Rich phonological neighbourhoods such as those which characterize the lexicons of
more advanced child learners or adult speakers indeed constitute powerful networks for the
processing of phonological representations, whose effects have been noted in tasks such as word
learning, lexical retrieval, and the detection of speech errors (e.g. Storkel 2006; Storkel,
8 Of course, as noted in the relevant literature, these behaviours are arguably governed by a number of non-linguistic, personality-related traits which may also yield different degrees of self-censorship on the part of different children.
27
Armbruster & Hogan 2006; Storkel 2011; White & Morgan 2008; see also Stamer & Vitevitch
2012; Chan & Vitevitch 2015 for similar observations in second language development).
Behavioural differences in phonological processing observed across different age groups may
also be tied to the relative degree of inter-connectedness within lexicons, for which lexicon size
does matter, as suggested in much of the literature summarized in section 2.2 (see also
Pierrehumbert 2003, Munson, Kurtz & Windsor 2005, and references therein for additional
discussion).
Finally, our argument is compatible with the view recently expressed by Sosa & Stoel-
Gammon (2012) that "[i]t may be that in young children, both metrics [vocabulary size and
phonological knowledge] assess the same construct: the degree of abstract phonemic knowledge"
(p. 605). We contend, however, that while this must be true if the productive lexicon is used as a
metric of vocabulary size, it remains unclear whether this claim can be extended to the receptive
lexicon, the size of which is arguably larger across all developmental stages. This question, as
well as further explorations of the relationships between lexical knowledge and phonological
development, call for the incorporation of additional measures of the children's productive and
receptive lexicons, which we hope to consider in future research.
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